Method for controlling diameter of grin lens fiber and fiber drawing equipment

ABSTRACT

When a GRIN lens fiber is drawn from a preform, control of a fiber diameter is improved in order to increase a production yield of the GRIN lens fiber having a fiber diameter within a desired range. The problem is solved by controlling the drawing speed using a fiber diameter c, which is obtained by correcting a fiber diameter a using the fiber diameter b and a fiber diameter α. The fiber diameter a is measured using a diameter measuring instrument A that measures an outer diameter of the GRIN lens fiber, which is being elongated inside a heating furnace, the fiber diameter b is measured using a diameter measuring instrument B that measures an outer diameter of the GRIN lens fiber outside the heating furnace, and the fiber diameter α is a value of the fiber diameter a measured a specified period of time T earlier.

TECHNICAL FIELD

The present invention relates to a method for controlling a fiberdiameter and equipment for drawing a GRIN lens fiber used when the GRINlens fiber is drawn from a preform.

BACKGROUND ART

A so-called GRIN lens is a cylindrical graded index lens (GRaded INdexlens) having a refraction index distribution within glass so as to benda traveling direction of light, thereby realizing the function of thelens. Typically, the GRIN lens is cut into pieces of less than about 1mm, each of which is fused to the tip of an optical fiber, and used in avariety of applications in optical systems for optical communications.Today, there is a demand for GRIN lenses having high NA (numericalaperture). Preforms of such GRIN lenses are fabricated in a sol-gelmethod as disclosed in Patent Document 1 below and the like. A preformthat is fabricated using the sol-gel method has a cylindrical shapewhose diameter and length are respectively about 5 mm and 30 to 50 mm atthe minimum. This size is very small compared to that of a preform foran ordinary optical fiber.

When the preform is drawn into the GRIN fiber lens, a fiber diameter iscontrolled as follows. That is, a diameter measuring instrument thatmeasures the fiber diameter of the drawn GRIN lens fiber is providedoutside a heating furnace that heats the preform so as to elongate thepreform. A measured value (fiber diameter) is transmitted to anautomatic controller and used to control a drawing speed such that thefiber diameter becomes closer to a target value.

Patent Document 2 below discloses a method for controlling an outerdiameter of a preform when a silica glass ingot for an optical fiber iselongated so as to form a preform. According to this technology,diameter measuring instruments are provided at two positions in themiddle of a part of the preform being elongated in a heating furnace. Anelongation speed is controlled on the basis of outer diameters of thepreform measured at the two positions.

Patent Document 1: Japanese Unexamined Patent Application PublicationNo. 2005-115097

Patent Document 2: Japanese Unexamined Patent Application PublicationNo. 10-167745

DISCLOSURE OF INVENTION Problems to be Solved by the Invention

Typically, in drawing an optical fiber, a fiber diameter is measured ata position away from a heating furnace so as to measure an outerdiameter that has been stabilized. The drawing speed is controlled inaccordance with the measured value so as to draw a fiber having aconstant outer diameter. The size of the preform of the optical fiber isφ30 to 80 mm in diameter, φ150 mm in diameter for a large preform, and 1to 1.5 m in the entire length. With consideration of operation time andthe like, the drawing speed is frequently several hundred m/minute, andaccordingly, it is supposed that the optical fiber reaches the diametermeasuring instrument in less than a second from the heating furnace evenwhen the heating furnace and the diameter measuring instrument arespaced away from each other by about several meters.

Likewise, in a process for drawing a GRIN lens, the diameter measuringinstrument is also disposed outside the heating furnace. However, thesize of the preform of the GRIN lens is sometimes less than 1% of thatof the optical fiber at the minimum, and the drawing speed thereof isseveral m/minute. Even when the diameter measuring instrument isdisposed at a position closest to the heating furnace, the distancebetween the center of the heating furnace and the diameter measuringinstrument is 200 mm. This means that there is a delay of severalseconds between the elongation of the preform and the measurement of thefiber diameter when the preform is drawn at a normal speed. The fiberdiameter control cannot be suitably performed on the basis of measuredvalues obtained in this method, and accordingly, the yield is notdesirable.

To overcome the above situation, in order to allow measurement of thefiber diameter in a timing when the elongation of the GRIN lens fiberhas been almost completed in the heating furnace, a diameter measurementis performed using a method as follows. That is, through a hole formedon a side surface of the furnace body, the fiber diameter is measuredusing an image processing system having a camera. However, a depth offocus decreases due to the distance to a target (a fiber), an angle offield, the precision of the lens, and the like. Accordingly, it is noteasy to focus on the target. In addition, due to convection of an inertgas used to purge the heating furnace, a neck-down position, resonanceof the GRIN lens fiber being drawn, and the like, the position of theGRIN lens fiber, which is the target of the measurement, may not beconstant. Accordingly, it may be difficult to correctly measure thefiber diameter.

There are light-blocking type dimension measuring devices and the likeother than the camera type. However, none of such devices performhigh-precision measurement when a light emitter and a light receiver arespaced apart so as to be positioned at one and the opposite sides of theheating furnace. Thus, those devices are regarded as unsuitable tomeasurement and control of the fiber diameter in the heating furnace andintroduction of those devices are difficult.

The technology in the above-described Patent Document 2 controls theelongation speed on the basis of measured outer diameter values of thepreform at two positions. Outer diameter measuring devices at the twopositions each measure the outer diameter inside the heating furnace.However, in this case, a target of measurement is φ0 to 80 mm, which islarge. Accordingly, it is easy to capture an image of the target, andthe measurement is less affected by an environment inside the furnacesuch as turbulence of a purge gas.

An object of the present invention is to improve control of a fiberdiameter when a GRIN lens fiber is drawn from a preform in order toincrease a production yield of the GRIN lens fiber having a fiberdiameter within a desired range.

Means for Solving the Problems

The present invention is a method for controlling a diameter of a GRINlens fiber. In the method, an outer diameter of the GRIN lens fiber iscontrolled so as to, when the GRIN lens fiber is drawn from a preform,make the outer diameter match a specified diameter. In the method, adrawing speed is controlled on the basis of a fiber diameter a that ismeasured using a diameter measuring instrument A that measures the outerdiameter of the GRIN lens fiber, which is being elongated in a heatingfurnace, and a fiber diameter b that is measured using a diametermeasuring instrument B that measures the outer diameter of the GRIN lensfiber outside the heating furnace (Claim 1).

Specifically, in the controlling method based on the fiber diameter aand the fiber diameter b, the drawing speed may be controlled using afiber diameter c, which is obtained by correcting the fiber diameter ausing the fiber diameter b and a fiber diameter α. In this case, thefiber diameter a is measured using the diameter measuring instrument Athat measures the outer diameter of the GRIN lens fiber, which is beingelongated inside the heating furnace, the fiber diameter b is measuredusing the diameter measuring instrument B that measures the outerdiameter of the GRIN lens fiber outside the heating furnace, and thefiber diameter α is a value of the fiber diameter a measured a specifiedperiod of time T earlier (Claim 2). In this case, the fiber diameter cis transmitted to an automatic controller, thereby allowing automaticcontrol to be performed so as to make the fiber diameter close to atarget value.

Since the fiber diameter a is a measurement of the fiber diameter insidethe heating furnace, it is incorrect because of the above-describedreasons. In contrast, the fiber diameter b is positioned outside theheating furnace, and measured under conditions compliant withspecifications of the measuring device, and accordingly, should be acorrect value. When the distance between the diameter measuringinstrument A and the diameter measuring instrument B is determined, andthe drawing speed is the normal speed, a fiber diameter measured usingthe diameter measuring instrument B at a certain time is close to thefiber diameter α, which is a value measured using the diameter measuringinstrument A a specified period of time T before the certain time. Thus,by comparing the fiber diameter b and the fiber diameter α, the degreeof error in the fiber diameter a, which is a value measured using thediameter measuring instrument A, can be recognized. By correcting thefiber diameter a using the fiber diameter b and the fiber diameter α,the fiber diameter c, which is the fiber diameter of an actually drawnpart (inside the heating furnace) can be measured with high precision.

Specifically, the fiber diameter c, which is a corrected fiber diametera, may be given by the following expression:

fiber diameter c=fiber diameter a+fiber diameter b−fiber diameter α

(Claim 3).

In the expression, (fiber diameter b−fiber diameter a) represents adifference between the diameter measuring instrument B (a correctmeasured value) and the diameter measuring instrument A (an incorrectmeasured value), both of which measure almost the same part of the GRINlens fiber, that is, a measurement error of the diameter measuringinstrument A (difference D). By adding the difference D to the fiberdiameter a, the measured value using the diameter measuring instrument A(the incorrect measured value) is corrected and becomes closer to thecorrect value.

Specifically, when the distance in a GRIN lens fiber path between ameasurement position of the diameter measuring instrument A and ameasurement position of the diameter measuring instrument B is d mm, andthe drawing speed is V in mm/second, the specified period of time T maybe given by the following expression:

(d−20)/V≦T≦(d+20)/V

(Claim 4).

The “distance in a GRIN lens fiber path” is a length of the GRIN lensfiber between the measurement position (the center of the measurementposition) of the diameter measuring instrument A and the measurementposition (the center of the measurement position) of the diametermeasuring instrument B.

When T=d/V, the fiber diameter α is a measured value using the diametermeasuring instrument A at a position that is completely the same as theposition of the GRIN lens fiber that is measured using the diametermeasuring instrument B. Although this is most preferable, since thedrawing speed varies in accordance with the control, it is difficultthat T=d/V completely holds. When T falls within (d±20)/V, the distancein the GRIN lens fiber between the measurement positions of the fiberdiameter b and the fiber diameter α is within ±20 mm. Thus, correctfiber diameter control can be performed substantially without problems.

In order to further reduce the error, the drawing speed may also becontrolled using the fiber diameter c that is obtained as follows. Thatis, the drawing speed at a time when a signal is received is detected,the specified period of time T is calculated from the speed, and thefiber diameter c is obtained by correcting the fiber diameter a usingthe fiber diameter b, which is a measured value at the time using thediameter measuring instrument B, and a fiber diameter α, which is ameasured value using the diameter measuring device A measured at a timea specified period of time T earlier than the time when the signal isreceived.

Specifically, PI control or PID control, which is one of the most commonmethods for automatic control, may be used as the method for controllingthe drawing speed (Claim 5).

According to the present invention, equipment for drawing a GRIN lensincludes a diameter measuring instrument A that measures an outerdiameter of a GRIN lens fiber, which is being elongated inside a heatingfurnace, and a diameter measuring instrument B that measures the outerdiameter of the GRIN lens fiber outside the heating furnace. Theequipment for drawing a GRIN lens controls a drawing speed on the basisof a fiber diameter a that is measured using the diameter measuringinstrument A and a fiber diameter b that is measured using the diametermeasuring instrument B (Claim 6).

This is the equipment for drawing a GRIN lens for performing the methodfor controlling a diameter of a GRIN lens fiber according to Claim 1.

Specifically, control based on the fiber diameter a and fiber diameter bmay include a correction device and an automatic controller. In thiscase, the correction device transmits a fiber diameter c to theautomatic controller. The fiber diameter c is obtained by correcting thefiber diameter a using the fiber diameter b and a fiber diameter α. Thefiber diameter a is measured using the diameter measuring instrument Athat measures the outer diameter of the GRIN lens fiber, which is beingelongated inside the heating furnace, the fiber diameter b is measuredusing the diameter measuring instrument B that measures the outerdiameter of the GRIN lens fiber outside the heating furnace, and thefiber diameter α is a value of the fiber diameter α measured a specifiedperiod of time T earlier. In this case, the automatic controller canperform automatic control of the drawing speed so as to make the fiberdiameter close to a target value (Claim 7).

This is the equipment for drawing a GRIN lens for performing the methodfor controlling a diameter of a GRIN lens fiber according to Claim 2.

Specifically, the fiber diameter c, which is a corrected fiber diametera, may be given by the following expression:

fiber diameter c=fiber diameter a+fiber diameter b−fiber diameter α

(Claim 8).

This is the equipment for drawing a GRIN lens for performing the methodfor controlling a diameter of a GRIN lens fiber according to Claim 3.

Specifically, when a distance between a measurement position of thediameter measuring instrument A and a measurement position of thediameter measuring instrument B in a GRIN lens path is d mm, and thedrawing speed is V mm/second, the specified period of time T may begiven by the following expression:

(d−20)/V≦T≦(d+20)/V

(Claim 9).

This is the equipment for drawing a GRIN lens fiber for performing themethod for controlling a diameter of a GRIN lens fiber according toClaim 4.

Specifically, the automatic controller that controls the drawing speedmay include a PID controller, which is one of the most common automaticcontrollers. In this case, PI control or PID control using the PIDcontroller is used to control the drawing speed (Claim 10).

In the present invention, the measurement position of the fiber diameterof the GRIN lens fiber inside the heating furnace using the diametermeasuring instrument A is preferably a position where elongation of thepreform has been almost completed. This position is typically a positionaway from the maximum temperature portion (the center of a heatingportion) of a heater by 70 mm or further. This position changes inaccordance with conditions such as a temperature in drawing and thedrawing speed.

The measurement error of the diameter measuring instrument A derivesfrom the fact that the diameter measuring instrument A is likely to beaffected by the environment inside the heating furnace and the state ofthe fiber due to the shallow depth of focus of the lens used for thecamera. Since the operation time of the GRIN lens fiber drawing isshort, a significant change in the environment during the drawing doesnot frequently occur. Thus, the degree of variation is comparativelysmall compared to the variation in the fiber diameter. With regard todirections of the error, the errors tend to occur in one of thedirections relative to a target diameter.

As described above, the position of the diameter measuring instrument Ais a position where elongation of the preform has been almost completed,and at the position outside the furnace, at which the diameter measuringinstrument B is disposed, the elongation is fully completed. Thus, thefiber diameters measured using the diameter measuring instruments A andB basically match to each other.

The distance between the positions at which diameter measuringinstrument A and the diameter measuring instrument B are disposed areconstant, and the specified period of time T required for the fiber tomove from A to B is determined if the drawing speed is constant. Thus,it can be said that the fiber diameter b, which is a value measured atthe moment when the fiber passes the diameter measuring instrument B, isthe fiber diameter a measured a specified period of time T earlier usingthe diameter measuring instrument A.

With regard to a transition of the fiber diameter of the GRIN lens fiberduring drawing, the variation in the fiber diameter is large at thestart of the drawing operation, and the degree of variation is decreasedusing fiber diameter control. When the variation in the fiber diameterhas been decreased, and the fiber diameter a is becoming closer to thetarget diameter, the degree of variation in the drawing speed alsodecreases. Thus, the time taken for the fiber to move from the diametermeasuring instrument A to the diameter measuring instrument B fallswithin the following range:

(d−20)/V≦T≦(d+20)/V.

Thus, the fiber diameter can be corrected so as to become very close toan actual value of the fiber diameter at the measurement position of thefiber diameter a. That is, the corrected fiber diameter c that is inputto the automatic controller is very close to an actual value of thefiber diameter of the GRIN lens that has been almost elongated insidethe heating furnace, and accordingly, preferable fiber diameter controlcan be performed.

When the variation in the fiber diameter during drawing is large and thedrawing speed varies due to fiber diameter control, the differencebetween the fiber diameter b and the fiber diameter a, which is measuredusing the diameter measuring instrument A the specified period of time Tearlier, increases as long as the specified period of time T is fixed.Preferably, the fiber diameter is corrected when fiber diameter controlstabilizes to some degree. Specifically, it is preferable that thecorrection is performed about 60 to 90 seconds after the start ofdrawing.

Advantages

In the method for controlling a diameter of a GRIN lens fiber and afiber drawing equipment according the present invention, a fiberdiameter that is very close to an actual value of the fiber diameter ofthe GRIN lens that has been almost elongated inside the heating furnacecan be input to the automatic controller in order to control the fiberdiameter. Thus, compared to the related-art method and equipment, thefiber diameter of the fabricated GRIN lens fiber is close to the targetvalue and has a decreased variation, and accordingly, the GRIN lensfiber having fiber diameter errors within an allowable range can befabricated while achieving a high yield.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an explanatory view of equipment for drawing a GRIN lensaccording to an embodiment (when a drawing speed is controlled).

FIG. 2 is an explanatory view of the equipment for drawing a GRIN lensaccording to the embodiment (when a preform is set).

FIG. 3 is an explanatory view of the equipment for drawing a GRIN lensaccording to the embodiment (when a timer starts).

FIG. 4 is a flowchart of a correction device.

REFERENCE NUMERALS

1 heating furnace

2 heater

3 ascending/descending device

4 winding drum

5 diameter measuring instrument A

6 diameter measuring instrument B

7 sensor

8 correction device

9 automatic controller

10 preform

11 GRIN lens fiber

12 weight

13 silica rod

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment

FIGS. 1 to 3 illustrate equipment for drawing a GRIN lens fiberaccording to an embodiment. This drawing equipment includes a heatingfurnace 1, a heater 2, an ascending/descending device 3, a winding drum4, a diameter measuring instrument A (5), a diameter measuringinstrument B (6), a sensor 7, a correction device 8, and an automaticcontroller 9.

The heating furnace 1 is a very high temperature vertical pipe furnace,the temperature of which can be increased up to 2100° C.

The winding drum 4 includes a horizontal movement mechanism thatprevents a turn of a fiber from overlapping another turn of the fiber.In the present embodiment, a drawn GRIN lens is directly wound using thewinding drum 4. By controlling a rotation speed of the winding drum 4, adrawing speed is controlled. A capstan roller may be provided before thewinding drum in order to control the drawing speed by controlling arotation speed of the capstan roller.

The diameter measuring instrument A (5) uses a commercial imageprocessing device using a camera. The camera needs to be calibrated inadvance using an object such as an optical fiber having a knowndimension.

A fiber diameter a, which is measured using the diameter measuringinstrument A, is transmitted to the correction device 8.

The diameter measuring instrument A (5) is provided at a position inwhich elongation of a GRIN lens fiber is substantially complete. In thepresent embodiment, the position is 80 mm below the center of a heatingportion of the heater 2.

The diameter measuring instrument B (6) uses a commercial outer diametermeasuring device of a light-blocking type. A fiber diameter b, which ismeasured using the diameter measuring instrument B, is transmitted tothe correction device 8.

The measurement position of the diameter measuring instrument B (6) ispreferably a position close to the exit of the heating furnace as muchas possible. In the present embodiment, the measurement position of thediameter measuring instrument B (6) is positioned about 200 mm below themeasurement position of the diameter measuring instrument A. Since thepath of the GRIN lens fiber is vertical, the distance d in the GRIN lensfiber path between the measurement positions of the diameter measuringinstrument A and the diameter measuring instrument B is about 200 mm.

As illustrated in FIG. 3, the sensor 7 detects that a lower end of aweight 12 has passed the sensor 7, and transmits a detection signal tothe correction device 8.

The correction device 8 outputs to the automatic controller 9 a fiberdiameter c in accordance with the fiber diameter a from the diametermeasuring instrument A and the fiber diameter b from the diametermeasuring instrument B.

The automatic controller 9 controls the rotation speed (the drawingspeed) of the winding drum such that the fiber diameter c becomes closerto a specified target value. By controlling the rotation speed of thewinding drum, the drawing speed at which the GRIN lens fiber is drawn iscontrolled.

A trigger of fiber diameter correction can be not only transmitted fromthe sensor 7 but also manually transmitted.

Next, the embodiment of a method for controlling a diameter of a GRINlens according to the present invention will be described.

After the temperature of the heating furnace 1 has been increased up toa specified temperature, the winding drum 4 is caused to start rotationand a horizontal movement. A preform 10 with a silica rod 13 weldedthereto is disposed in the ascending/descending device 3.

The ascending/descending device 3 is started to descend so as to descendthe preform 10 to a specified position. This state is illustrated inFIG. 2. When the preform 10 is softened and the weight 12 is descendedby a certain distance to a lower side of the heating furnace, theascending/descending device 3 is started to descend at a constant speed.The descending speed is a constant speed that corresponds to the drawingspeed of the GRIN lens.

As illustrated in FIG. 3, the moment when the lower end of the weight 12passes the sensor 7, the detection signal of the sensor 7 is transmittedto the correction device 8. This turns on a timer of the correctiondevice 8. The timer is set to count an appropriate time (85 seconds inthe present embodiment) for the fiber diameter of the GRIN lens fiberhaving been drawn to stabilize. When the set time has elapsed (when thetimer reaches 0), the correction device 8 performs correction of thefiber diameter a, and transmits the corrected value, the fiber diameterc, to the automatic controller 9. Before the timer reaches 0, thedifference between the fiber diameter α and the fiber diameter b is notcalculated, and a+0 is set to the fiber diameter c.

When the weight 12 is descended near the winding drum 4, the weight 12is detached, an end of an elongated part is attached to the winding drum4 using adhesive tape, and winding and drawing begin. Also at this time,automatic controller 9 is started.

An average rotation speed of the winding drum 4 for a preform having aparticular diameter is set so as to correspond to a ratio between afeeding speed and a target diameter. However, before the timer reaches0, the difference between the fiber diameter a and the fiber diameter bis not calculated. Therefore, the automatic controller 9 performsautomatic control in accordance with the fiber diameter c to which a+0is set. Thus, the average rotation speed of the winding drum 4constantly changes.

After 54 seconds from the start of drawing, the fiber diameter wasstabilized by the automatic control. When 85 seconds had elapsed and thetimer reached 0, the correction device 8 started correction. At thistime, the fiber diameter a, which was a measured value using thediameter measuring unit A, was 125.3 μm. The fiber diameter b, which wasa measured value using the diameter measuring instrument B, was 121.7μm, a value that was smaller than the fiber diameter a by 3.6 μm. Thus,it is observed that the measured value using the diameter measuringinstrument A has an error.

The correction is performed by calculating the fiber diameter c that isobtained by adding a difference (fiber diameter b−fiber diameter α) tothe fiber diameter a, where α is a fiber diameter measured using thediameter measuring instrument A before T seconds, a specified period oftime. That is, fiber diameter c=fiber diameter a+fiber diameter b−fiberdiameter α. The fiber diameter c is transmitted from the correctiondevice 8 to the automatic controller 9, where the automatic correctionis performed such that the fiber diameter c becomes closer to the targetvalue of 124.5 μm. In the present embodiment, the specified period oftime T varies between the 1.9 to 1.99 seconds in 10 ms. Since thedrawing speed V is about 106.7 mm/second, and the distance d between themeasurement position of the diameter measuring instrument A and themeasurement position of the diameter measuring instrument B is about 200mm, T varies substantially in the following range:

(d−12.3)V≦T≦(d−2.7)/V

That is, T falls within (d±20)/V, and the distance in the GRIN lensbetween the measurement positions of the fiber diameter b and the fiberdiameter α is within ±20 mm. Thus, fiber diameter control can beperformed substantially without problems.

In several seconds after the correction has started, the fiber diameterb (an actual fiber diameter of the GRIN lens fiber) substantially fallswithin a range of 124.5±1 μm. Thus, a fiber having a desirable fiberdiameter can be obtained.

Referring to FIG. 4, a program of the correction device 8 will bedescribed below.

After the program is started, whether or not the lower end of the weight12 reaches the sensor 7 as illustrated in FIG. 3 is determined in step101, “WEIGHT 12 PASSED SENSOR 7?” If a “NO” is returned, step 101 isrepeated and a waiting state is entered until the lower end of theweight 12 reaches the sensor 7. If a “YES” is returned, the programproceeds to step 102.

In step 102, a “START TIMER” operation is performed in order to turn“ON” the timer included in the correction device 8. A period of timesuitable to stabilizing the fiber diameter of the drawn GRIN lens fiber(85 seconds in the present embodiment) has been set to the timer.

In step 103, “TIMER REACHES 0?”, whether or not the set period of time(85 seconds) has elapsed is determined. If “NO” is returned, the programproceeds to step 104. If “YES” is returned, the program proceeds to acorrection operation beginning in step 105.

In step 104, an operation of “OBTAIN FIBER DIAMETER c (FIBER DIAMETERa+0) FROM CORRECTION DEVICE 8 AND TRANSMIT FIBER DIAMETER c TO AUTOMATICCONTROLLER 9” is performed. At this time, since the correction operation(difference D=fiber diameter b−fiber diameter α) has not been performed,the difference D is 0, and the fiber diameter α obtained from thediameter measuring instrument A is transmitted to the automaticcontroller 9 as the fiber diameter c. This operation is repeated atintervals of 10 ms until the timer reaches 0. The automatic controllerperforms automatic control such that the fiber diameter a transmittedfrom the correction device becomes closer to a preset target value of124.5 μm.

After it has been determined that the timer reaches “0” in step 103, an“OBTAIN FIBER DIAMETER a FROM MEMORY AND FIBER DIAMETERS a and b FROMDIAMETER MEASURING INSTRUMENTS A and B” operation is performed in step105.

The memory is included in the correction device. In the memory, 20 fiberdiameters a, which have been transmitted from the diameter measuringinstrument A at intervals of 100 ms, are sequentially stored. When thenumber of the transmitted fiber diameters a exceeds 20, the fiberdiameters a are sequentially discarded from the top (first stored). Thatis, the fiber diameter a stored in the top location is measured 1.9seconds before the last stored fiber diameter a. Since the fiberdiameter α (fiber diameter a stored in the top location) is obtained inevery 10 ms (0.01 seconds), the fiber diameter α to be obtained is afiber diameter measured 1.9 to 1.99 seconds before. At the same time,the present fiber diameters a and b are obtained from the diametermeasuring instruments A and B.

In step 106, “COMPUTE DIFFERENCE D=FIBER DIAMETER b−FIBER DIAMETER α”,the difference D is computed.

The fiber diameter b is a measured value presently measured using thediameter measuring instrument B. The fiber diameter α is a measuredvalue of a part of the GRIN lens near a part where the fiber diameter bis measured using the diameter measuring instrument A 1.9 to 1.99seconds earlier. The fiber diameter b is correctly measured. Since thefiber diameter α is measured in the furnace, it is highly probable thatthe measured value is incorrect. “DIFFERENCE D=FIBER DIAMETER b−FIBERDIAMETER α” equals to a measurement error of the diameter measuringinstrument A.

In step 107, a “COMPUTE FIBER DIAMETER c=FIBER DIAMETER a+DIFFERENCE DAND TRANSMIT FIBER DIAMETER c TO AUTOMATIC CONTROLLER” operation isperformed.

The fiber diameter c is obtained by correcting the fiber diameter apresently measured using the diameter measuring instrument A so as toeliminate (or reduce) the measurement error. Thus, the fiber diameter crepresents an almost correct fiber diameter at the measurement positionof the diameter measuring instrument A. The fiber diameter c istransmitted to the automatic controller 9, which then performs automaticcontrol such that the fiber diameter c transmitted from the correctiondevice becomes closer to a preset target value of 124.5 μm.

As described above, according to the present invention, the fiberdiameter of the preform in the heating furnace at a part that has beenalmost completely elongated (fiber diameter c) can be correctlymeasured. By performing automatic control in accordance with this fiberdiameter, the acceptable product ratio (yield) is significantly improvedcompared to the related art method.

Table 1 shows the results of drawing performed five times in accordancewith the above-described embodiment. Table 2 shows the results ofcomparative examples in which drawing is performed five times using arelated-art automatic control method (other conditions are the same asthose of the embodiment). In the related-art method, automatic controlis performed only on the basis of the fiber diameter b measured usingthe diameter measuring instrument B installed outside the heatingfurnace.

TABLE 1 Acceptable product ratio (%) Example 1 53.20 Example 2 59.19Example 3 71.89 Example 4 78.61 Example 5 54.77 Average 63.53

TABLE 2 Acceptable product ratio (%) Comparative example 1 42.81Comparative example 2 24.94 Comparative example 3 43.32 Comparativeexample 4 31.81 Comparative example 5 48.14 Average 38.20

In Tables 1 and 2, “Acceptable product ratio” represents the ratio of alength that is compliant with the specification (target diameter±1.0 μm)to the entire length in percentage. As clearly seen from Tables 1 and 2,the acceptable product ratio increases by 25% on average according tothe present invention compared to that with the related art method.

1-5. (canceled)
 6. An apparatus for drawing a GRIN lens fiber, saidapparatus comprising: a diameter measuring instrument A for measuring anouter diameter of a GRIN lens fiber, the GRIN lens fiber being elongatedinside a heating furnace; a diameter measuring instrument B formeasuring the outer diameter of the GRIN lens fiber outside the heatingfurnace; and a control device for controlling a drawing speed on thebasis of a fiber diameter a measured using the diameter measuringinstrument A and a fiber diameter b measured using the diametermeasuring instrument B.
 7. The apparatus for drawing a GRIN lens fiberaccording to claim 6, further comprising an automatic controller and acorrection device, wherein the correction device transmits a fiberdiameter c to the automatic controller, the fiber diameter c beingobtained by correcting the fiber diameter α using the fiber diameter band a fiber diameter a, the fiber diameter α being a value of the fiberdiameter a measured a specified period of time T earlier, the automaticcontroller controlling the drawing speed on the basis of the fiberdiameter c.
 8. The apparatus for drawing a GRIN lens fiber according toclaim 7, wherein the fiber diameter c is given by the followingexpression: fiber diameter a+fiber diameter b−fiber diameter a.
 9. Theapparatus for drawing a GRIN lens fiber according to claim 7, wherein,when a distance in a GRIN lens fiber path between a measurement positionof the diameter measuring instrument A and a measurement position of thediameter measuring instrument B is d mm, and the drawing speed in is Vmm/second, the specified period of time T seconds falls within thefollowing range:(d−20)/V≦T≦(d+20)/V.
 10. The apparatus for drawing a GRIN lens fiberaccording to claim 7, wherein the automatic controller includes a PIDcontroller, the PID controller controlling the drawing speed using PIcontrol or PID control.
 11. The apparatus for drawing a GRIN lens fiberaccording to claim 8, wherein, when a distance in a GRIN lens fiber pathbetween a measurement position of the diameter measuring instrument Aand a measurement position of the diameter measuring instrument B is dmm, and the drawing speed in is V mm/second, the specified period oftime T seconds falls within the following range:(d−20)/V≦T≦(d+20)/V.
 12. The apparatus for drawing a GRIN lens fiberaccording to claim 8, wherein the automatic controller includes a PIDcontroller, the PID controller controlling the drawing speed using PIcontrol or PID control.
 13. The apparatus for drawing a GRIN lens fiberaccording to claim 9, wherein the automatic controller includes a PIDcontroller, the PID controller controlling the drawing speed using PIcontrol or PID control.
 14. A method for controlling a diameter of aGRIN lens fiber, said method comprising: controlling an outer diameterof the GRIN lens fiber so as to, when the GRIN lens fiber is drawn froma preform, make the outer diameter match a specified diameter;controlling a drawing speed on the basis of: a fiber diameter a that ismeasured using a diameter measuring instrument A that measures the outerdiameter of the GRIN lens fiber, the GRIN lens fiber being elongated ina heating furnace, a fiber diameter b that is measured using a diametermeasuring instrument B that measures the outer diameter of the GRIN lensfiber outside the heating furnace; wherein the drawing speed is furthercontrolled on the basis of a fiber diameter c, the fiber diameter cbeing obtained by correcting the fiber diameter a using the fiberdiameter b and a fiber diameter α, the fiber diameter α being a value ofthe fiber diameter a measured a specified period of time T earlier, andwherein the fiber diameter c is given by the following expression: fiberdiameter a+fiber diameter b−fiber diameter α, wherein, when a distancein a GRIN lens path between a measurement position of the diametermeasuring instrument A and a measurement position of the diametermeasuring instrument B is d mm, and the drawing speed is V mm/second,the specified period of time T seconds falls within the following range:(d−20)/V≦T≦(d+20)/V.